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Paper detail

Cryogenic Optomechanics with a Si3N4 Membrane and Classical Laser Noise

We demonstrate a cryogenic optomechanical system comprising a flexible Si3N4 membrane placed at the center of a free-space optical cavity in a 400 mK cryogenic environment. We observe a mechanical quality factor Q > 4 x 10^6 for the 261-kHz fundamental drum-head mode of the membrane, and a cavity resonance halfwidth of 60 kHz. The optomechanical system therefore operates in the resolved sideband limit. We monitor the membrane's thermal motion using a heterodyne optical circuit capable of simultaneously measuring both of the mechanical sidebands, and find that the observed optical spring and damping quantitatively agree with theory. The mechanical sidebands exhibit a Fano lineshape, and to explain this we develop a theory describing heterodyne measurements in the presence of correlated classical laser noise. Finally, we discuss the use of a passive filter cavity to remove classical laser noise, and consider the future requirements for laser cooling this relatively large and low-frequency mechanical element to very near its quantum mechanical ground state.

preprint2012arXivOpen access
A. M. JayichJ. C. SankeyK. BorkjeD. LeeC. YangM. UnderwoodL. ChildressA. PetrenkoS. M. GirvinJ. G. E. Harris
cond-mat.mes-hallphysics.opticsquant-ph
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A. M. JayichJ. C. SankeyK. BorkjeD. LeeC. YangM. UnderwoodL. ChildressA. PetrenkoS. M. GirvinJ. G. E. Harris

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